<p>Dark pions are promising dark matter candidates, yet most analyses rely on leading-order (LO) chiral perturbation theory (ChPT). Motivated by the fact that, even for QCD <i>ππ</i> scattering, LO ChPT near threshold underestimates the isoscalar <i>s</i>-wave amplitude by an 𝒪(1) factor relative to high-precision dispersive results, we quantify how unitarization modifies the standard LO ChPT picture using the chiral unitary method — a nonperturbative resummation that implements the correct analytic structure with minimal input — and assess its impact on the phenomenology of dark-pion DM, taking SIMP and WIMP scenarios as canonical examples. We fix the subtraction constant to its natural estimate, interpreted as an effective cutoff at Λ<sub><i>χ</i></sub> = 4<i>πf</i><sub><i>π</i></sub>, so that the unitarized amplitudes depend only on <i>m</i><sub><i>π</i></sub> and <i>f</i><sub><i>π</i></sub>. We show that, depending on the coupling <i>m</i><sub><i>π</i></sub>/<i>f</i><sub><i>π</i></sub>, the unitarized amplitudes develop resonance poles absent at LO, leading to sizable departures in 2 → 2 self-scattering, relevant for SIMP scenarios, and in annihilation including initial-state interaction effects, relevant for WIMP scenarios. These modifications, in turn, affect the viable parameter space. Although the subtraction constant is, from a model-building perspective, merely a parameter, a substantial deviation from its natural value would point to additional elementary resonances with the same quantum numbers.</p>

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Dark-pion dark matter beyond leading order: unitarized chiral dynamics

  • Yuki Watanabe

摘要

Dark pions are promising dark matter candidates, yet most analyses rely on leading-order (LO) chiral perturbation theory (ChPT). Motivated by the fact that, even for QCD ππ scattering, LO ChPT near threshold underestimates the isoscalar s-wave amplitude by an 𝒪(1) factor relative to high-precision dispersive results, we quantify how unitarization modifies the standard LO ChPT picture using the chiral unitary method — a nonperturbative resummation that implements the correct analytic structure with minimal input — and assess its impact on the phenomenology of dark-pion DM, taking SIMP and WIMP scenarios as canonical examples. We fix the subtraction constant to its natural estimate, interpreted as an effective cutoff at Λχ = 4πfπ, so that the unitarized amplitudes depend only on mπ and fπ. We show that, depending on the coupling mπ/fπ, the unitarized amplitudes develop resonance poles absent at LO, leading to sizable departures in 2 → 2 self-scattering, relevant for SIMP scenarios, and in annihilation including initial-state interaction effects, relevant for WIMP scenarios. These modifications, in turn, affect the viable parameter space. Although the subtraction constant is, from a model-building perspective, merely a parameter, a substantial deviation from its natural value would point to additional elementary resonances with the same quantum numbers.